Hybrid Decision Trees: Longer Quantum Time is Strictly More Powerful

Abstract

In this paper, we introduce the hybrid query complexity, denoted as Q(f;q), which is the minimal query number needed to compute f, when a classical decision tree is allowed to call q'-query quantum subroutines for any q'≤ q. We present the following results: There exists a total Boolean function f such that Q(f;1) = O(R(f)4/5). Q(f;q) = (bs(f)/q + bs(f)) for any Boolean function f; the lower bound is tight when f is the O R function. Q(g X ORC n;1) = (n) for some sufficiently large constant C, where g := B OOLS IMONn is a variant of Simon's problem. Note that Q(g X ORC n) = O(polylog\; n). Therefore an exponential separation is established. Furthermore, this open the road to prove the conjecture ∀ k,\,Q(g X ORC k+1 n;k n) = (n), which would imply the oracle separation HP(QSIZE(nα))O ⊂neq BQPO for any α, where HP(QSIZE(nα)) is a complexity class that contains BQTIME(nα)BPP and BPPBQTIME(nα) in any relativized world.